The present invention relates to an assembly for an assembled container house system. The assembly includes: a first main wallboard, where the first main wallboard has a rectangular body; an upper right portion of the body of the first main wallboard protrudes rightwards to form a spherical protrusion, and a lower right portion extends rightwards to form an extension portion; an upper left portion of the body of the first main wallboard extends leftwards to form an extension portion, and a lower let portion protrudes leftwards to form a spherical protrusion; spherical recessed cavities are formed on front end surfaces of the two extension portions by means of being recessed backwards; the spherical protrusions match the spherical recessed cavities; and an axial direction of the spherical protrusion is perpendicular to an axial direction of the spherical recessed cavity. The assembly for an assembled container house system may be assembled into members with different lengths, different heights, different widths, and different colors, such as a house, a large shed, a cabinet, and a box, as well as toys. Moreover, independently used bathrooms, living rooms, and washbasin systems may be derived. Various components are reliably connected, may be repeatedly used, are suitable for industrial standardized and mass production, and facilitate transportation and splicing.

The present invention relates to an assembly for an assembled container house system. The assembly includes: a first main wallboard, where the first main wallboard has a rectangular body; an upper right portion of the body of the first main wallboard protrudes rightwards to form a spherical protrusion, and a lower right portion extends rightwards to form an extension portion; an upper left portion of the body of the first main wallboard extends leftwards to form an extension portion, and a lower let portion protrudes leftwards to form a spherical protrusion; spherical recessed cavities are formed on front end surfaces of the two extension portions by means of being recessed backwards; the spherical protrusions match the spherical recessed cavities; and an axial direction of the spherical protrusion is perpendicular to an axial direction of the spherical recessed cavity. The assembly for an assembled container house system may be assembled into members with different lengths, different heights, different widths, and different colors, such as a house, a large shed, a cabinet, and a box, as well as toys. Moreover, independently used bathrooms, living rooms, and washbasin systems may be derived. Various components are reliably connected, may be repeatedly used, are suitable for industrial standardized and mass production, and facilitate transportation and splicing.

A shear transfer system is provided. In the system a shear tie strap is attached to a first framing member, a second framing member, a third framing member, a fourth framing member, and a fifth framing member of a frame in a framed building. The second, third, fourth, and fifth framing members are orthogonal or oblique to the first framing member. More than one shear tie strap may be present in the framed building.

A shed roofing structure includes: a corner rafter in which a top surface and a bottom surface form a mountain profile having a width-direction center as the vertex, the corner rafter exhibiting a fletched profile as seen in cross-section; a valley rafter formed by vertically inverting the corner rafter; a plurality of common rafters which are disposed horizontally spaced apart at a flat section of the inclined roof and inclined along a roof gradient; and a receiving plate member that is placed on respective top surfaces of an elongate transverse rafter which intersects the plurality of common rafters and supports at least the plurality of common rafters and the valley rafter from below, and a vertical member which supports the corner rafter from below, and that receives the corner rafter, the valley rafter, and the common rafters.

A shear transfer system is provided. In the system, a shear tie strap is attached to a first framing member, a second framing member, a third framing member, a fourth framing member, and a fifth framing member of a frame in a framed building. The second, third, fourth, and fifth framing members are orthogonal or oblique to the first framing member. More than one shear tie strap may be present in the framed building.

A shear transfer system is provided. In the system, a shear tie strap is attached to a first framing member, a second framing member, a third framing member, a fourth framing member, and a fifth framing member of a frame in a framed building. The second, third, fourth, and fifth framing members are orthogonal or oblique to the first framing member. More than one shear tie strap may be present in the framed building.

The present invention relates to an assembly for an assembled container house system. The assembly includes: a first main wallboard, where the first main wallboard has a rectangular body; an upper right portion of the body of the first main wallboard protrudes rightwards to form a spherical protrusion, and a lower right portion extends rightwards to form an extension portion; an upper left portion of the body of the first main wallboard extends leftwards to form an extension portion, and a lower let portion protrudes leftwards to form a spherical protrusion; spherical recessed cavities are formed on front end surfaces of the two extension portions by means of being recessed backwards; the spherical protrusions match the spherical recessed cavities; and an axial direction of the spherical protrusion is perpendicular to an axial direction of the spherical recessed cavity. The assembly for an assembled container house system may be assembled into members with different lengths, different heights, different widths, and different colors, such as a house, a large shed, a cabinet, and a box, as well as toys. Moreover, independently used bathrooms, living rooms, and washbasin systems may be derived. Various components are reliably connected, may be repeatedly used, are suitable for industrial standardized and mass production, and facilitate transportation and splicing.

The present invention relates to an assembly for an assembled container house system. The assembly includes: a first main wallboard, where the first main wallboard has a rectangular body; an upper right portion of the body of the first main wallboard protrudes rightwards to form a spherical protrusion, and a lower right portion extends rightwards to form an extension portion; an upper left portion of the body of the first main wallboard extends leftwards to form an extension portion, and a lower let portion protrudes leftwards to form a spherical protrusion; spherical recessed cavities are formed on front end surfaces of the two extension portions by means of being recessed backwards; the spherical protrusions match the spherical recessed cavities; and an axial direction of the spherical protrusion is perpendicular to an axial direction of the spherical recessed cavity. The assembly for an assembled container house system may be assembled into members with different lengths, different heights, different widths, and different colors, such as a house, a large shed, a cabinet, and a box, as well as toys. Moreover, independently used bathrooms, living rooms, and washbasin systems may be derived. Various components are reliably connected, may be repeatedly used, are suitable for industrial standardized and mass production, and facilitate transportation and splicing.

Structural connectors used as a component to construct an arch including a plurality of closely adjacent, polygonal rows of stringer beams. The multiple row polygonal arch is a low-cost, general purpose support structure for bridges, shelters and arbors applicable to many cost-, time- or environmentally-sensitive situations. The structural connectors may be a Y-shaped connectors with three brackets, two upper brackets and a lower bracket, which collectively enable a union of three beams forming one node of the multiple row polygonal arch. Using these Y-shaped connectors to join the beams at each node creates the arch structure, and additionally provides the features of cantilevering, modularity, generic component shape, reusability and safety. Structural connectors are applicable to a variety of structures such as pedestrian and vehicular bridges, shelters, arbors, as well as jewelry, furniture and toys. Other aspects, embodiments, and features are also included.

Structural connectors used as a component to construct an arch including a plurality of closely adjacent, polygonal rows of stringer beams. The multiple row polygonal arch is a low-cost, general purpose support structure for bridges, shelters and arbors applicable to many cost-, time- or environmentally-sensitive situations. The structural connectors may be a Y-shaped connectors with three brackets, two upper brackets and a lower bracket, which collectively enable a union of three beams forming one node of the multiple row polygonal arch. Using these Y-shaped connectors to join the beams at each node creates the arch structure, and additionally provides the features of cantilevering, modularity, generic component shape, reusability and safety. Structural connectors are applicable to a variety of structures such as pedestrian and vehicular bridges, shelters, arbors, as well as jewelry, furniture and toys. Other aspects, embodiments, and features are also included.